1 00:00:00 --> 00:00:00 2 00:00:00 --> 00:00:02 The following content is provided under a Creative 3 00:00:02 --> 00:00:03 Commons license. 4 00:00:03 --> 00:00:06 Your support will help MIT OpenCourseWare continue to 5 00:00:06 --> 00:00:09 offer high quality educational resources for free. 6 00:00:09 --> 00:00:12 To make a donation, or to view additional materials from 7 00:00:12 --> 00:00:15 hundreds of MIT courses, visit MIT OpenCourseWare 8 00:00:15 --> 00:00:22 at ocw.mit.edu. 9 00:00:22 --> 00:00:24 PROFESSOR: Today we're going to continue with integration. 10 00:00:24 --> 00:00:29 And we get to do the probably the most important thing 11 00:00:29 --> 00:00:31 of this entire course. 12 00:00:31 --> 00:00:33 Which is appropriately named. 13 00:00:33 --> 00:00:50 It's called the fundamental theorem of calculus. 14 00:00:50 --> 00:00:55 And we'll be abbreviating it FTC and occasionally I'll put 15 00:00:55 --> 00:00:59 in a 1 here, because there will be two versions of it. 16 00:00:59 --> 00:01:01 But this is the one that you'll be using the 17 00:01:01 --> 00:01:06 most in this class. 18 00:01:06 --> 00:01:14 The fundamental theorem of calculus says the following. 19 00:01:14 --> 00:01:27 It says that if F' = f, so F' ( x) = little f ( x), there's a 20 00:01:27 --> 00:01:37 capital F and a little f, then the integral from a to b of 21 00:01:37 --> 00:01:52 f ( x) = F ( b) - F (a). 22 00:01:52 --> 00:01:52 That's it. 23 00:01:52 --> 00:01:55 That's the whole theorem. 24 00:01:55 --> 00:02:00 And you may recognize it. 25 00:02:00 --> 00:02:08 Before, we had the notation that f was the antiderivative, 26 00:02:08 --> 00:02:11 that is, capital F was the integral of f(x). 27 00:02:11 --> 00:02:12 We wrote it this way. 28 00:02:12 --> 00:02:14 This is this indefinite integral. 29 00:02:14 --> 00:02:17 And now we're putting in definite values. 30 00:02:17 --> 00:02:20 And we have a connection between the two uses 31 00:02:20 --> 00:02:22 of the integral sign. 32 00:02:22 --> 00:02:24 But with the definite values, we get real numbers out 33 00:02:24 --> 00:02:26 instead of a function. 34 00:02:26 --> 00:02:29 Or a function up to a constant. 35 00:02:29 --> 00:02:30 So this is it. 36 00:02:30 --> 00:02:32 This is the formula. 37 00:02:32 --> 00:02:35 And it's usually also written with another notation. 38 00:02:35 --> 00:02:40 So I want to introduce that notation to you as well. 39 00:02:40 --> 00:02:44 So there's a new notation here. 40 00:02:44 --> 00:02:47 Which you'll find very convenient. 41 00:02:47 --> 00:02:51 Because we don't always have to give a letter f to 42 00:02:51 --> 00:02:52 the functions involved. 43 00:02:52 --> 00:02:54 So it's an abbreviation. 44 00:02:54 --> 00:02:57 For right now there'll be a lot of f's, but anyway. 45 00:02:57 --> 00:02:59 So here's the abbreviation. 46 00:02:59 --> 00:03:04 Whenever I have a difference between a function at two 47 00:03:04 --> 00:03:10 values, I also can write this as F ( x) with an a down 48 00:03:10 --> 00:03:12 here and a b up there. 49 00:03:12 --> 00:03:16 So that's the notation that we use. 50 00:03:16 --> 00:03:20 And you can also, for emphasis, and this sometimes turns out to 51 00:03:20 --> 00:03:23 be important, when there's more than one variable floating 52 00:03:23 --> 00:03:25 around in the problem. 53 00:03:25 --> 00:03:28 To specify that the variable is x. 54 00:03:28 --> 00:03:32 So this is the same thing as x = a. 55 00:03:32 --> 00:03:34 And x = b. 56 00:03:34 --> 00:03:36 It indicates where you want to plug in, what 57 00:03:36 --> 00:03:37 you want to plug in. 58 00:03:37 --> 00:03:41 And now you take the top value minus the bottom value. 59 00:03:41 --> 00:03:43 So F ( b) - F(a). 60 00:03:43 --> 00:03:50 So this is just a notation, and in that notation, of course, 61 00:03:50 --> 00:03:59 the theorem can be written with this set of symbols here. 62 00:03:59 --> 00:04:04 Equally well. 63 00:04:04 --> 00:04:06 So let's just give a couple of examples. 64 00:04:06 --> 00:04:08 The first example is the one that we did last 65 00:04:08 --> 00:04:12 time very laboriously. 66 00:04:12 --> 00:04:15 If you take the function capital F(x), which happens 67 00:04:15 --> 00:04:23 to be x^3 / 3, then if you differentiate it, you get, 68 00:04:23 --> 00:04:25 well, the the factor of 3 cancels. 69 00:04:25 --> 00:04:29 So you get x^2, that's the derivative. 70 00:04:29 --> 00:04:34 And so by the fundamental theorem, so this implies by the 71 00:04:34 --> 00:04:42 fundamental theorem, that the integral from say, a to b of 72 00:04:42 --> 00:04:50 x^3 over - sorry, x^2 dx, that's the derivative here. 73 00:04:50 --> 00:04:55 This is the function we're going to use as f ( x) here 74 00:04:55 --> 00:05:00 = this function here. 75 00:05:00 --> 00:05:02 F ( b) - F ( a), that's here. 76 00:05:02 --> 00:05:04 This function here. 77 00:05:04 --> 00:05:10 So that's write F(b) - F( a), and that's equal 78 00:05:10 --> 00:05:19 to b^3 / 3 - a^3 / 3. 79 00:05:19 --> 00:05:24 Now, in this new notation, we usually don't have 80 00:05:24 --> 00:05:25 all of these letters. 81 00:05:25 --> 00:05:26 All we write is the following. 82 00:05:26 --> 00:05:28 We write the integral from a to be, and I'm going to do the 83 00:05:28 --> 00:05:30 case 0 to b, because that was the one that we actually 84 00:05:30 --> 00:05:31 did last time. 85 00:05:31 --> 00:05:35 So I'm going to set a = 0 here. 86 00:05:35 --> 00:05:39 And then, the problem we were faced last time as this. 87 00:05:39 --> 00:05:41 And as I said we did it very laboriously. 88 00:05:41 --> 00:05:47 But now you can see that we can do it in ten 89 00:05:47 --> 00:05:48 seconds, let's say. 90 00:05:48 --> 00:05:52 Well, the antiderivative of this is x^3 / 3. 91 00:05:52 --> 00:05:55 I'm going to evaluate it at 0 and at b and subtract. 92 00:05:55 --> 00:06:00 So that's going to be b^3 / 3 - 0^3 / 3. 93 00:06:00 --> 00:06:03 Which of course is b^3 / 3. 94 00:06:03 --> 00:06:06 And that's the end, that's the answer. 95 00:06:06 --> 00:06:08 So this is a lot faster than yesterday. 96 00:06:08 --> 00:06:10 I hope you'll agree. 97 00:06:10 --> 00:06:15 And we can dispense with those elaborate computations. 98 00:06:15 --> 00:06:18 Although there's a conceptual reason, a very important one, 99 00:06:18 --> 00:06:21 for understanding the procedure that we went through. 100 00:06:21 --> 00:06:27 Because eventually you're going to be using integrals and these 101 00:06:27 --> 00:06:30 quick ways of doing things, to solve problems like finding 102 00:06:30 --> 00:06:32 the volumes of pyramids. 103 00:06:32 --> 00:06:34 In other words, we're going to reverse the process. 104 00:06:34 --> 00:06:42 And so we need to understand the connection between the two. 105 00:06:42 --> 00:06:45 I'm going to give a couple more examples. 106 00:06:45 --> 00:06:47 And then we'll go on. 107 00:06:47 --> 00:06:50 So the second example would be one that would be quite 108 00:06:50 --> 00:06:53 difficult to do by this Riemann sum technique that we 109 00:06:53 --> 00:06:55 described yesterday. 110 00:06:55 --> 00:06:57 Although it is possible. 111 00:06:57 --> 00:06:59 It uses much higher mathematics to do it. 112 00:06:59 --> 00:07:16 And that is the area under one hump of the sine curve, sine x. 113 00:07:16 --> 00:07:17 Let me just draw a picture of that. 114 00:07:17 --> 00:07:20 The curve goes like this, and we're talking 115 00:07:20 --> 00:07:21 about this area here. 116 00:07:21 --> 00:07:24 It starts out at 0, it goes to pi. 117 00:07:24 --> 00:07:28 That's one hump. 118 00:07:28 --> 00:07:31 And so the answer is, it's the integral from 119 00:07:31 --> 00:07:38 0 to pi of sin x dx. 120 00:07:38 --> 00:07:39 And so I need to take the antiderivative of that. 121 00:07:39 --> 00:07:42 And that's - cos x. 122 00:07:42 --> 00:07:46 That's the thing whose derivative is sin x. 123 00:07:46 --> 00:07:49 Evaluating it at 0 and pi. 124 00:07:49 --> 00:07:52 Now, let's do this one carefully. 125 00:07:52 --> 00:07:55 Because this is where I see a lot of arithmetic mistakes. 126 00:07:55 --> 00:07:57 Even though this is the easy part of the problem. 127 00:07:57 --> 00:08:02 It's hard to pay attention and plug in the right numbers. 128 00:08:02 --> 00:08:04 And so, let's just pay very close attention. 129 00:08:04 --> 00:08:05 I'm plugging in pi. 130 00:08:05 --> 00:08:08 That's - cos pi. 131 00:08:08 --> 00:08:09 That's the first term. 132 00:08:09 --> 00:08:13 And then I'm subtracting the value at the bottom, 133 00:08:13 --> 00:08:19 which is - cos 0. 134 00:08:19 --> 00:08:22 There are already five opportunities for you to make 135 00:08:22 --> 00:08:25 a transcription error or an arithmetic mistake 136 00:08:25 --> 00:08:26 in what I just did. 137 00:08:26 --> 00:08:30 And I've seen all five of them. 138 00:08:30 --> 00:08:34 So the next one is that this is - (- 1). 139 00:08:34 --> 00:08:36 Minus negative 1, if you like. 140 00:08:36 --> 00:08:41 And then this is minus, and here's another - 1. 141 00:08:41 --> 00:08:44 So altogether we have 2. 142 00:08:44 --> 00:08:44 So that's it. 143 00:08:44 --> 00:08:46 That's the area. 144 00:08:46 --> 00:09:02 This area, which is hard to guess, this is area 2. 145 00:09:02 --> 00:09:06 The third example is maybe superfluous but I'm 146 00:09:06 --> 00:09:10 going to say it anyway. 147 00:09:10 --> 00:09:16 We can take the integral, say, from 0 to 1, of x ^ 100. 148 00:09:17 --> 00:09:21 Any power, now, is within our power. 149 00:09:21 --> 00:09:24 So let's do it. 150 00:09:24 --> 00:09:27 So here we have the antiderivative is 151 00:09:27 --> 00:09:32 x ^ 101 / 101. 152 00:09:32 --> 00:09:36 Evaluate it at 0 and 1. 153 00:09:36 --> 00:09:42 And that is just 1 / 101. 154 00:09:42 --> 00:09:46 That's that. 155 00:09:46 --> 00:09:49 So that's the fundamental theorem. 156 00:09:49 --> 00:09:54 Now this, as I say, harnesses a lot of what we've already 157 00:09:54 --> 00:09:58 learned, all about antiderivatives. 158 00:09:58 --> 00:10:05 Now, I want to give you an intuitive interpretation. 159 00:10:05 --> 00:10:10 So let's try that. 160 00:10:10 --> 00:10:12 We'll talk about a proof of the fundamental theorem 161 00:10:12 --> 00:10:14 a little bit later. 162 00:10:14 --> 00:10:16 It's not actually that hard. 163 00:10:16 --> 00:10:22 But we'll give an intuitive reason, interpretation, 164 00:10:22 --> 00:10:28 if you like. 165 00:10:28 --> 00:10:37 Of the fundamental theorem. 166 00:10:37 --> 00:10:41 So this is going to be one which is not related to 167 00:10:41 --> 00:10:43 area, but rather to time and distance. 168 00:10:43 --> 00:10:55 So we'll consider x (t) is your position at time t. 169 00:10:55 --> 00:11:03 And then x' (t), which is dx/dt, is going to be what 170 00:11:03 --> 00:11:12 we know as your speed. 171 00:11:12 --> 00:11:18 And then what the theorem is telling us, is the following. 172 00:11:18 --> 00:11:24 It's telling us the integral from a to b of v ( t) dt. 173 00:11:24 --> 00:11:35 So, reading the relationship is equal to x (b) - x ( a). 174 00:11:35 --> 00:11:40 And so this is some kind of cumulative sum 175 00:11:40 --> 00:11:45 of your velocities. 176 00:11:45 --> 00:11:48 So let's interpret the right-hand side first. 177 00:11:48 --> 00:11:57 This is the distance traveled. 178 00:11:57 --> 00:12:03 And it's also what you would read on your odometer. 179 00:12:03 --> 00:12:05 Right, from the beginning to the end of the trip. 180 00:12:05 --> 00:12:07 That's what you would read on your odometer. 181 00:12:07 --> 00:12:19 Whereas this is what you would read on your speedometer. 182 00:12:19 --> 00:12:23 So this is the interpretation. 183 00:12:23 --> 00:12:25 Now, I want to just go one step further into this 184 00:12:25 --> 00:12:29 interpretation, to make the connection with the Riemann 185 00:12:29 --> 00:12:32 sums that we had yesterday. 186 00:12:32 --> 00:12:35 Because those are very complicated to understand. 187 00:12:35 --> 00:12:37 And I want you to understand them viscerally on 188 00:12:37 --> 00:12:39 several different levels. 189 00:12:39 --> 00:12:43 Because that's how you'll understand integration better. 190 00:12:43 --> 00:12:45 The first thing that I want to imagine, so we're going to do a 191 00:12:45 --> 00:12:47 thought experiment now, which is that you are 192 00:12:47 --> 00:12:50 extremely obsessive. 193 00:12:50 --> 00:12:55 And you're driving your car from time a to time b, place 194 00:12:55 --> 00:12:58 q to place r, whatever. 195 00:12:58 --> 00:13:03 And you check your speedometer every second. 196 00:13:03 --> 00:13:09 OK, so you've read your speedometer in the i'th second, 197 00:13:09 --> 00:13:12 and you've read that you're going at this speed. 198 00:13:12 --> 00:13:16 Now, how far do you go in that second? 199 00:13:16 --> 00:13:21 Well, the answer is you go this speed times the time interval, 200 00:13:21 --> 00:13:24 which in this case we're imagining as 1 second. 201 00:13:24 --> 00:13:25 Alright? 202 00:13:25 --> 00:13:28 So this is how far you went. 203 00:13:28 --> 00:13:29 But this is the time interval. 204 00:13:29 --> 00:13:40 And this is the distance traveled. in that a second 205 00:13:40 --> 00:13:46 number, i, in the i'th second. 206 00:13:46 --> 00:13:48 The distance traveled in the i'th second, that's a total 207 00:13:48 --> 00:13:49 distance you traveled. 208 00:13:49 --> 00:13:53 Now, what happens if you go the whole distance? 209 00:13:53 --> 00:13:56 Well, you travel the sum of all these distances. 210 00:13:56 --> 00:14:00 So it's some massive sum, where n is some ridiculous 211 00:14:00 --> 00:14:01 number of seconds. 212 00:14:01 --> 00:14:04 3600 seconds or something like that. 213 00:14:04 --> 00:14:05 Whatever it is. 214 00:14:05 --> 00:14:09 And that's going to turn out to be very similar to what you 215 00:14:09 --> 00:14:11 would read on your odometer. 216 00:14:11 --> 00:14:13 Because during that second, you didn't change 217 00:14:13 --> 00:14:14 velocity very much. 218 00:14:14 --> 00:14:18 So the approximation that the speed at one time that you 219 00:14:18 --> 00:14:21 spotted it is very similar to the speed during 220 00:14:21 --> 00:14:22 the whole second. 221 00:14:22 --> 00:14:24 It doesn't change that much. 222 00:14:24 --> 00:14:26 So this is a pretty good approximation to how 223 00:14:26 --> 00:14:29 far you traveled. 224 00:14:29 --> 00:14:33 And so the sum is a very realistic approximation 225 00:14:33 --> 00:14:34 to the entire integral. 226 00:14:34 --> 00:14:37 Which is denoted this way. 227 00:14:37 --> 00:14:40 Which, by the fundamental theorem, is exactly 228 00:14:40 --> 00:14:43 how far you traveled. 229 00:14:43 --> 00:14:46 So this is x ( b) - x (a). 230 00:14:46 --> 00:14:49 Exactly. 231 00:14:49 --> 00:14:55 The other one is approximate. 232 00:14:55 --> 00:15:08 OK, again this is called a Riemann sum. 233 00:15:08 --> 00:15:17 Alright so that's the intro to the fundamental theorem. 234 00:15:17 --> 00:15:23 And now what I need to do is extend it just a bit. 235 00:15:23 --> 00:15:29 And the way I'm going to extend it is the following. 236 00:15:29 --> 00:15:31 I'm going to do it on this example first. 237 00:15:31 --> 00:15:35 And then we'll do it more formally. 238 00:15:35 --> 00:15:39 So here's this example where we went someplace. 239 00:15:39 --> 00:15:44 But now I just want to draw you an additional picture here. 240 00:15:44 --> 00:15:49 Imagine I start here and I go over to there 241 00:15:49 --> 00:15:54 and then I come back. 242 00:15:54 --> 00:15:56 And maybe even I do a round trip. 243 00:15:56 --> 00:15:58 I come back to the same place. 244 00:15:58 --> 00:16:03 Well, if I come back to the same place, then the position 245 00:16:03 --> 00:16:06 is unchanged from the beginning to the end. 246 00:16:06 --> 00:16:08 In other words, the difference is 0. 247 00:16:08 --> 00:16:13 And the velocity, technically rather than the speed. 248 00:16:13 --> 00:16:15 It's the speed to the right and the the speed to the left maybe 249 00:16:15 --> 00:16:17 are the same, but one of them is going in the positive 250 00:16:17 --> 00:16:19 direction and one of them is going in the negative 251 00:16:19 --> 00:16:22 direction, and they cancel each other. 252 00:16:22 --> 00:16:25 So if you have this kind of situation, we want 253 00:16:25 --> 00:16:26 that to be reflected. 254 00:16:26 --> 00:16:29 We like that interpretation and we want to preserve it even 255 00:16:29 --> 00:16:35 when in the case when the function v is negative. 256 00:16:35 --> 00:16:47 And so I'm going to now extend our notion of integration. 257 00:16:47 --> 00:17:02 So we'll extend integration to the case f negative. 258 00:17:02 --> 00:17:04 Or positive. 259 00:17:04 --> 00:17:08 In other words, it could be any sign. 260 00:17:08 --> 00:17:10 Actually, there's no change. 261 00:17:10 --> 00:17:12 The formulas are all the same. 262 00:17:12 --> 00:17:15 We just, if this v is going to be positive, we write 263 00:17:15 --> 00:17:16 in a positive number. 264 00:17:16 --> 00:17:18 If it's going to be negative, we write in a negative number. 265 00:17:18 --> 00:17:20 And we just leave it alone. 266 00:17:20 --> 00:17:25 And the real, so here's, let me carry out an example 267 00:17:25 --> 00:17:29 and show you how it works. 268 00:17:29 --> 00:17:32 I'll carry out the example on this blackboard up here. 269 00:17:32 --> 00:17:33 Of the sine function. 270 00:17:33 --> 00:17:36 But we're going to try two humps. 271 00:17:36 --> 00:17:38 We're going to try the first hump and the one that 272 00:17:38 --> 00:17:40 goes underneath. 273 00:17:40 --> 00:17:40 There. 274 00:17:40 --> 00:17:44 So our example here is going to be the integral from 275 00:17:44 --> 00:17:50 0 to 2pi of sin x dx. 276 00:17:50 --> 00:17:54 And now, because the fundamental theorem is so 277 00:17:54 --> 00:17:58 important, and so useful, and so convenient, we just assume 278 00:17:58 --> 00:18:01 that it be true in this case as well. 279 00:18:01 --> 00:18:06 So we insist that this is going to be - cos x. 280 00:18:06 --> 00:18:08 Evaluate it at 0 and 2pi. 281 00:18:08 --> 00:18:10 With the difference. 282 00:18:10 --> 00:18:14 Now, when we carry out that difference, what we get here 283 00:18:14 --> 00:18:24 is - cos 2pi. - (- cos 0). 284 00:18:24 --> 00:18:33 Which is - 1 - (- 1), which is 0. 285 00:18:33 --> 00:18:39 And the interpretation of this is the following. 286 00:18:39 --> 00:18:43 Here's our double hump, here's pi and here's 2pi. 287 00:18:43 --> 00:18:46 And all that's happening is that the geometric 288 00:18:46 --> 00:18:49 interpretation that we had before of the area under 289 00:18:49 --> 00:18:52 the curve has to be taken with a grain of salt. 290 00:18:52 --> 00:18:54 In other words, I lied to you before when I said that the 291 00:18:54 --> 00:18:57 definite integral was the area under the curve. 292 00:18:57 --> 00:18:59 It's not. 293 00:18:59 --> 00:19:02 The definite integral is the area under the curve when it's 294 00:19:02 --> 00:19:05 above the curve, and it counts negatively when it's 295 00:19:05 --> 00:19:08 below the curve. 296 00:19:08 --> 00:19:12 So yesterday, my geometric interpretation was incomplete. 297 00:19:12 --> 00:19:19 And really just a plain lie. 298 00:19:19 --> 00:19:30 So the true geometric interpretation of the definite 299 00:19:30 --> 00:19:46 integral is plus the area above the axis, above the x 300 00:19:46 --> 00:20:00 axis, minus the area below the x axis. 301 00:20:00 --> 00:20:02 As in the picture. 302 00:20:02 --> 00:20:05 I'm just writing it down in words, but you should think 303 00:20:05 --> 00:20:08 of it visually also. 304 00:20:08 --> 00:20:12 So that's the setup here. 305 00:20:12 --> 00:20:17 And now we have the complete definition of integrals. 306 00:20:17 --> 00:20:20 And I need to list for you a bunch of their properties and 307 00:20:20 --> 00:20:21 how we deal with integrals. 308 00:20:21 --> 00:20:25 So are there any questions before we go on? 309 00:20:25 --> 00:20:25 Yeah. 310 00:20:25 --> 00:20:32 STUDENT: [INAUDIBLE] 311 00:20:32 --> 00:20:39 PROFESSOR: Right. 312 00:20:39 --> 00:20:42 So the question was, wouldn't the absolute value of the 313 00:20:42 --> 00:20:45 velocity function be involved? 314 00:20:45 --> 00:20:48 The answer is yes. 315 00:20:48 --> 00:20:51 That is, that's one question that you could ask. 316 00:20:51 --> 00:20:54 One question you could ask is what's the total 317 00:20:54 --> 00:20:57 distance traveled. 318 00:20:57 --> 00:21:01 And in that case, you would keep track of the absolute 319 00:21:01 --> 00:21:05 value of the velocity as you said. 320 00:21:05 --> 00:21:06 Whether it's positive or negative. 321 00:21:06 --> 00:21:08 And then you would get the total length of 322 00:21:08 --> 00:21:13 this curve here. 323 00:21:13 --> 00:21:18 That's, however, not what the definite integral measures. 324 00:21:18 --> 00:21:21 It measures the net distance traveled. 325 00:21:21 --> 00:21:24 So it's another thing. 326 00:21:24 --> 00:21:25 In other words, we can do that. 327 00:21:25 --> 00:21:27 We now have the tools to do both. 328 00:21:27 --> 00:21:35 We could also, so if you like, the total distance is equal 329 00:21:35 --> 00:21:39 to the integral of this. 330 00:21:39 --> 00:21:40 From a to b. 331 00:21:40 --> 00:21:48 But the net distance is the one without the 332 00:21:48 --> 00:21:54 absolute value signs. 333 00:21:54 --> 00:21:57 So that's correct. 334 00:21:57 --> 00:22:03 Other questions? 335 00:22:03 --> 00:22:04 Alright. 336 00:22:04 --> 00:22:23 So now, let's talk about properties of integrals. 337 00:22:23 --> 00:22:35 So the properties of integrals that I want to mention 338 00:22:35 --> 00:22:39 to you are these. 339 00:22:39 --> 00:22:47 The first one doesn't bear too much comment. 340 00:22:47 --> 00:22:53 If you take the cumulative integral of a sum, you're just 341 00:22:53 --> 00:23:01 trying to get the sum of the separate integrals here. 342 00:23:01 --> 00:23:03 And I won't say much about that. 343 00:23:03 --> 00:23:06 That's because sums come out, the because the 344 00:23:06 --> 00:23:07 integral is a sum. 345 00:23:07 --> 00:23:15 Incidentally, you know this strange symbol here, 346 00:23:15 --> 00:23:17 there's actually a reason for it historically. 347 00:23:17 --> 00:23:19 If you go back to old books, you'll see that it actually 348 00:23:19 --> 00:23:21 looks a little bit more like an s. 349 00:23:21 --> 00:23:24 This capital Sigma is a sum. 350 00:23:24 --> 00:23:27 S for sum, because everybody in those days knew 351 00:23:27 --> 00:23:28 Latin and Greek. 352 00:23:28 --> 00:23:31 And this one is also an s, but gradually it was such 353 00:23:31 --> 00:23:33 an important s that they made a bigger. 354 00:23:33 --> 00:23:35 And then they stretched it out and made it a little thinner, 355 00:23:35 --> 00:23:40 because it didn't fit into one typesetting space. 356 00:23:40 --> 00:23:43 And so just for typesetting reasons it got stretched. 357 00:23:43 --> 00:23:45 And got a little bit skinny. 358 00:23:45 --> 00:23:47 Anyway, so it's really an s. 359 00:23:47 --> 00:23:50 And in fact, in French they call it sum. 360 00:23:50 --> 00:23:53 Even though we call it integral. 361 00:23:53 --> 00:23:57 So it's a sum. 362 00:23:57 --> 00:24:00 So it's consistent with sums in this way. 363 00:24:00 --> 00:24:09 And similarly, similarly we can factor constants out of sums. 364 00:24:09 --> 00:24:20 So if you have an integral like this, the constant factors out. 365 00:24:20 --> 00:24:25 But definitely don't try to get a function out of this. 366 00:24:25 --> 00:24:27 That won't happen. 367 00:24:27 --> 00:24:30 OK, in other words, c has to be a constant. 368 00:24:30 --> 00:24:41 Doesn't depend on x. 369 00:24:41 --> 00:24:44 The third property. 370 00:24:44 --> 00:24:46 What do I want to call the third property here? 371 00:24:46 --> 00:24:51 I have sort of a preliminary property, yes, here. 372 00:24:51 --> 00:24:52 Which is the following. 373 00:24:52 --> 00:24:53 And I'll draw a picture of it. 374 00:24:53 --> 00:24:59 I suppose you have three points along a line. 375 00:24:59 --> 00:25:01 So then I'm going to draw a picture that. 376 00:25:01 --> 00:25:03 And I'm going to use the interpretation above the 377 00:25:03 --> 00:25:05 curve, even though that's not the whole thing. 378 00:25:05 --> 00:25:07 So here's a, here's b and here's c. 379 00:25:07 --> 00:25:11 And you can see that the area of this piece, of the first 380 00:25:11 --> 00:25:14 two pieces here, when added together, gives you the 381 00:25:14 --> 00:25:15 area of the whole. 382 00:25:15 --> 00:25:19 And that's the rule that I'd like to tell you. 383 00:25:19 --> 00:25:24 So if you integrate from a to b, and you add to that the 384 00:25:24 --> 00:25:37 integral from b to c, you'll get the integral from a to c. 385 00:25:37 --> 00:25:39 This is going to be just a little preliminary, because 386 00:25:39 --> 00:25:41 the rule is a little better than this. 387 00:25:41 --> 00:25:47 But I will explain that in a minute. 388 00:25:47 --> 00:25:52 The fourth rule is a very simple one. 389 00:25:52 --> 00:26:00 Which is that the integral from a to a of f ( x ) dx = 0. 390 00:26:00 --> 00:26:02 Now, that you can see very obviously because 391 00:26:02 --> 00:26:04 there's no area. 392 00:26:04 --> 00:26:05 No horizontal movement there. 393 00:26:05 --> 00:26:08 The rectangle is infinitely thin, and there's 394 00:26:08 --> 00:26:10 nothing there. 395 00:26:10 --> 00:26:12 So this is the case. 396 00:26:12 --> 00:26:17 You can also interpret it a F ( a) - F ( a). 397 00:26:17 --> 00:26:21 So that's also consistent with our interpretation. 398 00:26:21 --> 00:26:24 In terms of the fundamental theorem of calculus. 399 00:26:24 --> 00:26:28 And it's perfectly reasonable that this is the case. 400 00:26:28 --> 00:26:33 Now, the fifth property is a definition. 401 00:26:33 --> 00:26:35 It's not really a property. 402 00:26:35 --> 00:26:38 But it's very important. 403 00:26:38 --> 00:26:46 The integral from a to b of f( x) dx = minus the integral 404 00:26:46 --> 00:26:50 from b to a, of f( x) dx. 405 00:26:50 --> 00:26:56 Now, really, the right-hand side here is an undefined 406 00:26:56 --> 00:26:58 quantity so far. 407 00:26:58 --> 00:27:05 We never said you could ever do this where the a < b. 408 00:27:05 --> 00:27:09 Because this is working backwards here. 409 00:27:09 --> 00:27:12 But we just have a convention that that's the definition. 410 00:27:12 --> 00:27:14 Whenever we write down this number, it's the same as 411 00:27:14 --> 00:27:17 minus what that number is. 412 00:27:17 --> 00:27:21 And the reason for all of these is again that we want them to 413 00:27:21 --> 00:27:22 be consistent with the fundamental theorem 414 00:27:22 --> 00:27:23 of calculus. 415 00:27:23 --> 00:27:26 Which is the thing that makes all of this work. 416 00:27:26 --> 00:27:31 So if you notice the left-hand side here is F ( b) 417 00:27:31 --> 00:27:34 - F ( a), capital F. 418 00:27:34 --> 00:27:36 The antiderivative of little f. 419 00:27:36 --> 00:27:40 On the other hand, the other side is minus, and if we just 420 00:27:40 --> 00:27:42 ignore that, we say these are letters, if we were a machine, 421 00:27:42 --> 00:27:44 we didn't know which one was bigger than which, we just 422 00:27:44 --> 00:27:50 plugged them in, we would get here F( a) - F( b), over here. 423 00:27:50 --> 00:27:53 And to make these two things equal, what we want is to 424 00:27:53 --> 00:27:54 put that minus sign in. 425 00:27:54 --> 00:27:59 Now it's consistent. 426 00:27:59 --> 00:28:04 So again, these rules are set up so that everything 427 00:28:04 --> 00:28:05 is consistent. 428 00:28:05 --> 00:28:11 And now I want to improve on rule 3 here. 429 00:28:11 --> 00:28:13 And point out to you. 430 00:28:13 --> 00:28:16 So let me just go back to rule 3 for a second. 431 00:28:16 --> 00:28:22 That now that we can evaluate integrals regardless of the 432 00:28:22 --> 00:28:26 order, we don't have to have a < b, b < c in order to 433 00:28:26 --> 00:28:28 make sense out of this. 434 00:28:28 --> 00:28:31 We actually have the possibility of considering 435 00:28:31 --> 00:28:34 integrals where the a's and the b's and the c's are 436 00:28:34 --> 00:28:36 in any order you want. 437 00:28:36 --> 00:28:38 And in fact, with this definition, with this 438 00:28:38 --> 00:28:43 definition 5, 3 works no matter what the numbers are. 439 00:28:43 --> 00:28:44 So this is much more convenient. 440 00:28:44 --> 00:28:49 We don't, this is not necessary. 441 00:28:49 --> 00:28:51 Not necessary. 442 00:28:51 --> 00:28:57 It just works using convention 5. 443 00:28:57 --> 00:29:04 OK, with 5. 444 00:29:04 --> 00:29:09 Again, before I go on, let me emphasize we really 445 00:29:09 --> 00:29:11 want to respect the sign of this velocity. 446 00:29:11 --> 00:29:15 We really want the net change in the position. 447 00:29:15 --> 00:29:18 And we don't want this absolute value here. 448 00:29:18 --> 00:29:20 Because otherwise, all of our formulas are going to mess up. 449 00:29:20 --> 00:29:22 We won't always be able to check. 450 00:29:22 --> 00:29:25 Sometimes you have letters rather than actual numbers 451 00:29:25 --> 00:29:28 here, and you won't know whether a is bigger than b. 452 00:29:28 --> 00:29:31 So you'll want to know that these formulas work and are 453 00:29:31 --> 00:29:36 consistent in all situations. 454 00:29:36 --> 00:29:39 OK, I'm going to trade these again. 455 00:29:39 --> 00:29:47 In order to preserve the ordering 1 through 5. 456 00:29:47 --> 00:29:54 And now I have a sixth property that I want to talk about. 457 00:29:54 --> 00:30:02 This one is called estimation. 458 00:30:02 --> 00:30:14 And it says the following. if f(x) <= g ( )x, then the 459 00:30:14 --> 00:30:21 integral from a to b of f(x) dx <= the integral from 460 00:30:21 --> 00:30:28 a to b of g (x) dx. 461 00:30:28 --> 00:30:36 Now, this one says that if I'm going more slowly than you, 462 00:30:36 --> 00:30:40 then you go farther than I do. 463 00:30:40 --> 00:30:41 OK. 464 00:30:41 --> 00:30:43 That's all it's saying. 465 00:30:43 --> 00:30:47 For this one, you'd better have a < b. 466 00:30:47 --> 00:30:49 You need it. 467 00:30:49 --> 00:30:55 Because we flip the signs when we flip the order of a and b. 468 00:30:55 --> 00:30:58 So this one, it's essential that the lower limit be 469 00:30:58 --> 00:31:04 smaller than the upper limit. 470 00:31:04 --> 00:31:07 But let me just emphasize, because we're dealing with 471 00:31:07 --> 00:31:08 the generalities of this. 472 00:31:08 --> 00:31:10 Actually if one of these is negative and the other one is 473 00:31:10 --> 00:31:14 negative, then it also works. 474 00:31:14 --> 00:31:17 This one ends up being, if f is more negative than g, then 475 00:31:17 --> 00:31:22 this added up thing is more negative than that one. 476 00:31:22 --> 00:31:25 Again, under the assumption that a < b. 477 00:31:25 --> 00:31:34 So as I wrote it's in full generality. 478 00:31:34 --> 00:31:37 Let's illustrate this one. 479 00:31:37 --> 00:31:47 And then we have one more property to learn after that. 480 00:31:47 --> 00:31:58 So let me give you an example of estimation. 481 00:31:58 --> 00:32:01 The example is the same as one that I already gave you. 482 00:32:01 --> 00:32:05 But this time, because we have the tool of integration, we 483 00:32:05 --> 00:32:11 can just follow our noses and it works. 484 00:32:11 --> 00:32:15 I start with the inequality, so I'm trying to illustrate 485 00:32:15 --> 00:32:17 estimation, so I want to start with an inequality which is 486 00:32:17 --> 00:32:19 what the hypothesis is here. 487 00:32:19 --> 00:32:21 And I'm going to integrate the inequality to 488 00:32:21 --> 00:32:22 get this conclusion. 489 00:32:22 --> 00:32:25 And see what conclusion it is. 490 00:32:25 --> 00:32:28 The inequality that I want to take is that e 491 00:32:28 --> 00:32:32 ^ x >= 1, for x >= 0. 492 00:32:32 --> 00:32:37 That's going to be our starting place. 493 00:32:37 --> 00:32:39 And now I'm going to integrate it. 494 00:32:39 --> 00:32:40 That is, I'm going to use estimation to 495 00:32:40 --> 00:32:42 see what that gives. 496 00:32:42 --> 00:32:45 Well, I'm going to integrate, say, from 0 to b. 497 00:32:45 --> 00:32:50 I can't integrate below 0 because it's only true above 0. 498 00:32:50 --> 00:33:01 This is e ^ x dx >= the integral from 0 to b of 1 dx. 499 00:33:01 --> 00:33:05 Alright, let's work out what each of these is. 500 00:33:05 --> 00:33:13 The first one, e ^ x dx, is, the antiderivative is e ^ 501 00:33:13 --> 00:33:16 x, evaluated at 0 and b. 502 00:33:16 --> 00:33:18 So that's e ^ b - e ^ 0. 503 00:33:18 --> 00:33:23 Which is e ^ b - 1. 504 00:33:23 --> 00:33:29 The other one, you're supposed to be able to get by 505 00:33:29 --> 00:33:32 the rectangle law. 506 00:33:32 --> 00:33:35 This is one rectangle of base b and height 1. 507 00:33:35 --> 00:33:37 So the answer is b. 508 00:33:37 --> 00:33:44 Or you can do it by antiderivatives, but it's b. 509 00:33:44 --> 00:33:49 That means that our inequality says if I just combine these 510 00:33:49 --> 00:33:55 two things together, that e ^ b - 1 >= b. 511 00:33:55 --> 00:34:02 And that's the same thing as e ^ b >= 1 + b. 512 00:34:02 --> 00:34:05 Again, this only works for b >= 0. 513 00:34:05 --> 00:34:10 Notice that if b were negative, this would be a well 514 00:34:10 --> 00:34:13 defined quantity. 515 00:34:13 --> 00:34:18 But this estimation would be false. 516 00:34:18 --> 00:34:22 We need that the b > 0 in order for this to make sense. 517 00:34:22 --> 00:34:24 So this was used. 518 00:34:24 --> 00:34:25 And that's a good thing, because this 519 00:34:25 --> 00:34:28 inequality is suspect. 520 00:34:28 --> 00:34:32 Actually, it turns out to be true when b is negative. 521 00:34:32 --> 00:34:38 But we certainly didn't prove it. 522 00:34:38 --> 00:34:42 I'm going to just repeat this process. 523 00:34:42 --> 00:34:46 So let's repeat it. 524 00:34:46 --> 00:34:50 Starting from the inequality, the conclusion, which 525 00:34:50 --> 00:34:51 is sitting right here. 526 00:34:51 --> 00:34:59 But I'll write it in a form e ^ x >= 1 + x, for x >= 0. 527 00:34:59 --> 00:35:03 And now, if I integrate this one, I get the integral from 0 528 00:35:03 --> 00:35:13 to b, e ^ x dx >= the integral from 0 to b, (1 + x) dx and I 529 00:35:13 --> 00:35:16 remind you that we've already calculated this one. 530 00:35:16 --> 00:35:19 This is e ^ b - 1. 531 00:35:19 --> 00:35:21 And the other one is not hard to calculate. 532 00:35:21 --> 00:35:25 The antiderivative is x + x^2 / 2. 533 00:35:25 --> 00:35:28 We're evaluating that at 0 and b. 534 00:35:28 --> 00:35:34 So that comes out to be b + b^2 / 2. 535 00:35:34 --> 00:35:42 And so our conclusion is that the left side, which is e 536 00:35:42 --> 00:35:48 ^ b - 1 >= b + b^2 / 2. 537 00:35:48 --> 00:35:51 And this is for b >= 0. 538 00:35:51 --> 00:36:00 And that's the same thing as e ^ b >= 1 + b + b^2 / 2. 539 00:36:00 --> 00:36:07 This one actually is false for b negative, so that's something 540 00:36:07 --> 00:36:15 that you have to be careful with the b positives here. 541 00:36:15 --> 00:36:19 So you can keep on going with this, and you 542 00:36:19 --> 00:36:20 didn't have to think. 543 00:36:20 --> 00:36:23 And you'll produce a very interesting polynomial, 544 00:36:23 --> 00:36:30 which is a good approximation to e^ b. 545 00:36:30 --> 00:36:34 So so that's it for the basic properties. 546 00:36:34 --> 00:36:38 Now there's one tricky property that I need to tell you about. 547 00:36:38 --> 00:36:47 It's not that tricky, but it's a little tricky. 548 00:36:47 --> 00:37:07 And this is change of variables. 549 00:37:07 --> 00:37:09 Change of variables in integration, we've 550 00:37:09 --> 00:37:11 actually already done. 551 00:37:11 --> 00:37:14 We called that, the last time we talked about it, 552 00:37:14 --> 00:37:23 we called it substitution. 553 00:37:23 --> 00:37:26 And the idea here, if you may remember, was that if you're 554 00:37:26 --> 00:37:34 faced with an integral like this, you can change it to, if 555 00:37:34 --> 00:37:38 you put in u = u (x) and you have a du, which is equal 556 00:37:38 --> 00:37:42 to u' ( x) du, dx, sorry. 557 00:37:42 --> 00:37:45 Then you can change the integral as follows. 558 00:37:45 --> 00:37:51 This is the same as g (u( x)) u' (x) dx. 559 00:37:51 --> 00:37:58 This was the general procedure for substitution. 560 00:37:58 --> 00:38:05 What's new today is that we're going to put in the limits. 561 00:38:05 --> 00:38:10 If you have a limit here, u1, and a limit here, u2, you want 562 00:38:10 --> 00:38:14 to know what the relationship is between the limits here and 563 00:38:14 --> 00:38:18 the limits when you change variables to the new variables. 564 00:38:18 --> 00:38:21 And it's the simplest possible thing. 565 00:38:21 --> 00:38:26 Namely the two limits over here are in the same relationship as 566 00:38:26 --> 00:38:29 u ( x) is to this symbol u here. 567 00:38:29 --> 00:38:35 In other words, u1 = u ( x1), and u2 = u(x2). 568 00:38:35 --> 00:38:39 That's what works. 569 00:38:39 --> 00:38:44 Now there's only one danger here, there's subtlety which 570 00:38:44 --> 00:39:02 is, this only works if u' does not change sign. 571 00:39:02 --> 00:39:04 I've been worrying a little bit about going backwards and 572 00:39:04 --> 00:39:07 forwards, and I allowed myself to reverse and do all kinds of 573 00:39:07 --> 00:39:09 stuff, right, with these integrals. 574 00:39:09 --> 00:39:11 So we're sort of free to do it. 575 00:39:11 --> 00:39:14 Well, this is one case where you want to avoid it, OK? 576 00:39:14 --> 00:39:15 Just don't do it. 577 00:39:15 --> 00:39:18 It is possible, actually, to make sense out of it, but it's 578 00:39:18 --> 00:39:21 also possible to get yourself infinitely confused. 579 00:39:21 --> 00:39:25 So just make sure that -- now it's OK is u' is always 580 00:39:25 --> 00:39:29 negative, or always going one way, so OK if u' is always 581 00:39:29 --> 00:39:31 positive, you're always going the other way, but if you mix 582 00:39:31 --> 00:39:39 them up you'll get yourself mixed up. 583 00:39:39 --> 00:39:46 Let me give you an example. 584 00:39:46 --> 00:39:54 The example will be maybe close to what we did last time. 585 00:39:54 --> 00:39:57 When we first did substitution. 586 00:39:57 --> 00:40:02 So the integral from 1 to 2, this time I'll put in definite 587 00:40:02 --> 00:40:09 limits, of x^2 plus -- sorry, maybe I call this x^3. x^3 + 588 00:40:09 --> 00:40:17 2, let's say, I don't know, to the 5th power, x^2 dx. 589 00:40:17 --> 00:40:20 So this is an example of an integral that we would 590 00:40:20 --> 00:40:25 have tried to handle by substitution before. 591 00:40:25 --> 00:40:36 And the substitution we would have used is u = x^3 + 2. 592 00:40:36 --> 00:40:38 And that's exactly what we're going to do here. 593 00:40:38 --> 00:40:44 But we're just going to also take into account the limits. 594 00:40:44 --> 00:40:47 The first step as in any substitution or change 595 00:40:47 --> 00:40:54 of variables, is this. 596 00:40:54 --> 00:40:57 And so we can fill in the things that we would 597 00:40:57 --> 00:40:58 have done previously. 598 00:40:58 --> 00:41:01 Which is that this is the integral and this is u ^ 5. 599 00:41:01 --> 00:41:09 And then because this is 3x^2, we see that this is 3. 600 00:41:09 --> 00:41:13 Sorry, let's write it the other way. 601 00:41:13 --> 00:41:17 1/3 du = x^2 dx. 602 00:41:17 --> 00:41:20 So that's what I'm going to plug in for this factor here. 603 00:41:20 --> 00:41:26 So here's 1/3 du, which replaces that. 604 00:41:26 --> 00:41:29 But now there's the extra feature. 605 00:41:29 --> 00:41:31 The extra feature is the limits. 606 00:41:31 --> 00:41:35 So here, really in disguise, because, and now this is 607 00:41:35 --> 00:41:38 incredibly important. 608 00:41:38 --> 00:41:44 This is one of the reasons why we use this notation dx and du. 609 00:41:44 --> 00:41:47 We want to remind ourselves which variable is involved 610 00:41:47 --> 00:41:49 in the integration. 611 00:41:49 --> 00:41:52 And especially if you're the one naming the variables, you 612 00:41:52 --> 00:41:54 may get mixed up in this respect. 613 00:41:54 --> 00:41:59 So you must know which variable is varying between 1 and 2. 614 00:41:59 --> 00:42:01 And the answer is, it's x is the one that's 615 00:42:01 --> 00:42:04 varying between 1 and 2. 616 00:42:04 --> 00:42:07 So in disguise, even though I didn't write it, it 617 00:42:07 --> 00:42:10 was contained in this little symbol here. 618 00:42:10 --> 00:42:11 This reminded us which variable. 619 00:42:11 --> 00:42:14 You'll find this amazingly important when you get to 620 00:42:14 --> 00:42:16 multivariable calculus. 621 00:42:16 --> 00:42:18 When there are many variables floating around. 622 00:42:18 --> 00:42:21 So this is an incredibly important distinction to make. 623 00:42:21 --> 00:42:23 So now, over here we have a limit. 624 00:42:23 --> 00:42:26 But of course it's supposed to be with respect to u, now. 625 00:42:26 --> 00:42:29 So we need to calculate what those corresponding limits are. 626 00:42:29 --> 00:42:33 And indeed it's just, I plug in here u1 is going to be able to 627 00:42:33 --> 00:42:35 what I plug in for x = 1, that's going to be 1 628 00:42:35 --> 00:42:38 ^3 + 2, which is 3. 629 00:42:38 --> 00:42:46 And then u2 is 2^3 + 2, which = 10, right? 630 00:42:46 --> 00:42:47 8 + 2 = 10. 631 00:42:47 --> 00:42:57 So this is the integral from 3 to 10, of u ^ 5 (1/3 du). 632 00:42:57 --> 00:43:00 And now I can finish the problem. 633 00:43:00 --> 00:43:06 This is 1/18 u ^ 6, from 3 to 10. 634 00:43:06 --> 00:43:10 And this is where the most common mistake occurs in 635 00:43:10 --> 00:43:12 substitutions of this type. 636 00:43:12 --> 00:43:16 Which is that if you ignore this, and you plug in these 1 637 00:43:16 --> 00:43:18 and 2 here, you think, oh I should just be putting 638 00:43:18 --> 00:43:20 it at 1 and 2. 639 00:43:20 --> 00:43:23 But actually, it should be, the u value that we're interested 640 00:43:23 --> 00:43:27 in, and the lower limit is u = 3 and u = 10 as 641 00:43:27 --> 00:43:29 the upper limit. 642 00:43:29 --> 00:43:31 So those are suppressed here. 643 00:43:31 --> 00:43:35 But those are the ones that we want. 644 00:43:35 --> 00:43:37 And so, here we go. 645 00:43:37 --> 00:43:41 It's 1/18 times some ridiculous number which I won't calculate. 646 00:43:41 --> 00:43:47 10 ^ 6 - 3 ^ 6. 647 00:43:47 --> 00:43:48 Yes, question. 648 00:43:48 --> 00:44:07 STUDENT: [INAUDIBLE] 649 00:44:07 --> 00:44:14 PROFESSOR: So, if you want to do things with where you're 650 00:44:14 --> 00:44:19 worrying about the sign change, the right strategy is, 651 00:44:19 --> 00:44:20 what you suggested works. 652 00:44:20 --> 00:44:22 And in fact I'm going to do an example right 653 00:44:22 --> 00:44:24 now on this subject. 654 00:44:24 --> 00:44:30 But, the right strategy is to break it up into pieces. 655 00:44:30 --> 00:44:34 Where u' has one sign or the other, OK? 656 00:44:34 --> 00:44:37 Let me show you an example. 657 00:44:37 --> 00:44:40 Where things go wrong. 658 00:44:40 --> 00:44:47 And I'll tell you how to handle it roughly. 659 00:44:47 --> 00:44:55 So here's our warning. 660 00:44:55 --> 00:45:00 Suppose you're integrating for - 1 to 1, x^2 dx. 661 00:45:00 --> 00:45:02 Here's an example. 662 00:45:02 --> 00:45:09 And you have the temptation to plug in u = x^2. 663 00:45:09 --> 00:45:11 Now, of course, we know how to integrate this. 664 00:45:11 --> 00:45:16 But let's just pretend we were stubborn and wanted 665 00:45:16 --> 00:45:19 to use substitution. 666 00:45:19 --> 00:45:26 Then we have du = 2x dx. 667 00:45:26 --> 00:45:30 And now if I try to make the correspondence, notice that 668 00:45:30 --> 00:45:38 the limits are u1 = (- 1)^2, that's the bottom limit. 669 00:45:38 --> 00:45:40 And u2 is the upper limit. 670 00:45:40 --> 00:45:43 That's 1 ^2, that's also equal to 1. 671 00:45:43 --> 00:45:45 Both limits are 1. 672 00:45:45 --> 00:45:47 So this is going from 1 to 1. 673 00:45:47 --> 00:45:53 And no matter what it is, we know it's going to be 0. 674 00:45:53 --> 00:45:55 But we know this is not 0. 675 00:45:55 --> 00:45:58 This is the integral of a positive quantity. 676 00:45:58 --> 00:46:03 And the area under a curve is going to be a positive area. 677 00:46:03 --> 00:46:04 So this is a positive quantity. 678 00:46:04 --> 00:46:07 It can't be 0. 679 00:46:07 --> 00:46:12 If you actually plug it in, it looks equally strange. 680 00:46:12 --> 00:46:14 You put in here this u and then, so that 681 00:46:14 --> 00:46:15 would be for the u^2. 682 00:46:16 --> 00:46:22 And then to plug in for dx, you would write dx = (1 / 2x) du. 683 00:46:22 --> 00:46:27 And then you might write that as this. 684 00:46:27 --> 00:46:31 And so what I should put in here is this quantity here. 685 00:46:31 --> 00:46:33 Which is a perfectly OK integral. 686 00:46:33 --> 00:46:37 And it has a value, I mean, it's what it is. 687 00:46:37 --> 00:46:39 It's 0. 688 00:46:39 --> 00:46:45 So of course this is not true. 689 00:46:45 --> 00:46:55 And the reason is that u = x^2, and u' ( x ) = 2x, which was 690 00:46:55 --> 00:47:00 positive for x positive, and negative for x negative. 691 00:47:00 --> 00:47:03 And this was the sign change which causes us trouble. 692 00:47:03 --> 00:47:08 If we break it off into its two halves, then it'll be OK and 693 00:47:08 --> 00:47:09 you'll be able to use this. 694 00:47:09 --> 00:47:12 Now, there was a mistake. 695 00:47:12 --> 00:47:15 And this was essentially what you were saying. 696 00:47:15 --> 00:47:19 That is, it's possible to see this happening as you're doing 697 00:47:19 --> 00:47:21 it if you're very careful. 698 00:47:21 --> 00:47:24 There's a mistake in this process, and the mistake 699 00:47:24 --> 00:47:26 is in the transition. 700 00:47:26 --> 00:47:28 This is a mistake here. 701 00:47:28 --> 00:47:33 Maybe I haven't used any red yet today, so I get 702 00:47:33 --> 00:47:34 to use some red here. 703 00:47:34 --> 00:47:36 Oh boy. 704 00:47:36 --> 00:47:38 This is not true, here. 705 00:47:38 --> 00:47:39 This step here. 706 00:47:39 --> 00:47:40 So why isn't it true? 707 00:47:40 --> 00:47:43 It's not true for the standard reason. 708 00:47:43 --> 00:47:50 Which is that really, x = plus or minus square root of u. 709 00:47:50 --> 00:47:54 And if you stick to one side or the other, you'll have 710 00:47:54 --> 00:47:55 a coherent formula for it. 711 00:47:55 --> 00:47:57 One of them will be the plus and one of them will be the 712 00:47:57 --> 00:47:59 minus and it will work out when you separate 713 00:47:59 --> 00:48:01 it into its pieces. 714 00:48:01 --> 00:48:02 So you could do that. 715 00:48:02 --> 00:48:04 But this is a can of worms. 716 00:48:04 --> 00:48:06 So I avoid this. 717 00:48:06 --> 00:48:10 And just do it in a place where the inverse is well defined. 718 00:48:10 --> 00:48:11 And where the function either moves steadily 719 00:48:11 --> 00:48:13 up or steadily down. 720 00:48:13 --> 00:48:14